Polyphase propylene polymer-rubber compositions and process for their preparation

ABSTRACT

Polyphase compositions having, as a continuous phase a propylene polymer and as a second phase a synthetic or natural rubber, are prepared by dispersing a propylene polymer of substantially all sub-micron particle size in the second phase and fusing the polymer under controlled conditions which assure the formation of the propylene polymer into a continuous phase.

United States Patent [151 3,665,059 Mahlman Ma 23 1972 POLYPHASE PROPYLENE POLYIVIER- References Cited RUBBER COMPOSITIONS AND UNITED STATES PATENTS PROCESS FOR THEIR PREPARATION 3,426,106 2/1969 Zijp et al ..260/897 [72] Inventor; n Mahlman, w Chester, p 3,352,817 11/1967 Meyer et al.... ..260/94.9

[73] Assignee: Hercules Incorporated, Wilmington, Del. FOREIGN PATENTS OR APPLICATIONS [22] Filed: June 26, 1970 1,022,628 3/ 1966 Great Britain ..260/897 pp No 301 897,643 5/1962 Great Britain ..260/897 Prima Examiner-Murra Tillman 11 Da '3 y Related U 8 App canon Assistant Examiner-C. J. Seccuro [63] Continuation-impart of Ser. No. 670,412, Sept. 25, AttorneyWilliam S. Alexander 1967, abandoned.

[57] ABSTRACT [52] US. Cl. ..260/897 A, 117/132 C, 117/133,

260/4 R 260/33 6 A 260/316 AQ 260/336 PO Polyphase compositlons havmg, as a continuous phase a 266/45 7 P 266/45 260/45 260/93 propylene polymer and as a second phase a synthetic or natu- 26O/8%6 260/88'9 260/897'C ral rubber, are prepared by dispersing a propylene polymer of Im Cl C08f 29/12 substantially all sub-micron particle size in the second phase 58] Field 889 4 and fusing the polymer under controlled conditions which assure the formation of the propylene polymer into a continuous phase.

7 Claims, No Drawings POLYPHASE PROPYLENE POLYMER-RUBBER COMPOSITIONS AND PROCESS FOR THEIR PREPARATION This application is a continuation-in-part of my application U.S. Ser. No. 670,412, filed Sept. 25, 1967 now abandoned.

This invention relates to unique polyphase compositions comprised of a crystallizable propylene polymer and amorphous second phase. More particularly, it relates to a technique for preparing such polyphase compositions whereby a uniform distribution of the phases can be effected.

In many cases, it is desired to blend propylene polymers with major amounts of other materials to modify either the properties of the polymer or those of the other material. For example, it is known to add various types of rubber to polypropylene to improve its low temperature impact strength, terpene polymers or rosin derivatives to impart low temperature impact strength or heat sealability, or amorphous polypropylene to improve flow properties. Propylene polymers are also employed as additives to lubricants to stifien the same and prevent splatter, and in some cases simply as a binder.

In applications such as those cited above and many others, the polymer is frequently present in the minor proportion and is intended to form a reinforcing phase supporting the other material. In actual practice, however, it is found extremely difficult, if at all possible, to incorporate the polymer uniformly enough that it can form a sufficiently disperse phase in the second material. This is due primarily to the very high melt viscosity of even low molecular weight propylene polymers as well as to the high melt viscosity of the second phase in many cases. Blending of the phases is accomplished in the melt and such high viscosity materials cannot be readily blended even with the most efficient, high shear, melt-compounding equipment known. As a result, the compositions previously known to the art consisted, usually, of extremely non-homogeneous mixtures having substantial regions of the polymer phase randomly located throughout with, generally, no interconnection between them to form a truly continuous phase. The resulting composition, thus, does not possess the optimum strength or other property which the polymer is intended to impart thereto.

Polypropylene, and other polymers of propylene, as provided by the prior art, and which have been employed in preparing the prior art compositions which might be said to compare with those prepared by the instant invention have been provided in the form of relatively large particles, usually not less than about 30 microns. It has been possible to reduce the polymer to smaller particles only with great difficulty and such reduction has not resulted in particles less than about -l 5 microns in size. When polymer particles of this size are dispersed in the second phase such as rubber, polyisobutylene, and the like, the relatively large size of the polymer particles causes relatively large distances between particles in the liquid medium prior to their dissolving even though the particles are uniformly dispersed therein. Thus, when the particles dissolve, a substantial amount of flow or diffusion between phases is required if a homogeneous solution of the polymer in the other phase is to be realized. Unfortunately, the high viscosity of the two phases efiectively prevents such diffusion unless extremely vigorous mixing conditions are employed. In most cases, the energy and temperature required are such as to result in degradation of the propylene polymer.

In accordance with this invention, an improved technique has been found for preparing homogeneous, polyphase structures containing a propylene polymer as a continuous phase. This technique is based on the discovery that the problems encountered in uniformly dispersing the polymer in the second phase can be substantially overcome by employing very finely divided polymer particles as the starting material. Stated more completely, the invention comprises a process for preparing solid, polyphase compositions containing (A) as a continuous phase, a crystallizable propylene polymer being present as a substantially continuous network in the crystalline but essentially non-spherulitic state, and having an intrinsic viscosity of at least about 2, and (B) as a second phase, a substantially amorphous organic material which has a theta temperature for the propylene polymer below about 160 C. and which can be maintained as a liquid at 1 10 to 250 C., is essentially a nonsolvent for said crystalline propylene polymer at temperatures below about C., has a cohesive energy density of from about 45 to about calories per cubic centimeter at 20 C., which process comprises rendering the amorphous material fluid and uniformly dispersing therein a propylene polymer in the form of particles having an average size of 0.02 to 0.5 micron, heating the total composition to a temperature at which the propylene polymer dissolves in the amorphous material and cooling. The propylene polymer continuous phase constitutes 5 to 60 percent, preferably 10 to 50 percent, by weight of the total composition.

By means of this invention, it is possible to form polyphase compositions having a propylene polymer continuous phase and a second phase comprising any natural or synthetic rubber.

The propylene polymer employed in the practice of this invention can have an intrinsic viscosity of from about 2 up to about 35, or even higher. The intrinsic viscosity (l.V. which is an indication of the molecular weight or degree of polymerization of the polymer, is important in that it affects the concentration of the polymer which is required to form the desired continuous phase. Lower concentrations of polymer are possible as the I.V. thereof increases. Useful compositions, exhibiting desirable properties, e.g., flexibility, ductility and tensile strength, can be prepared with as little as 5 percent of a polymer having an l.V. of 8 or higher. However, when the polymer I.V. is less than 8, the concentration will normally be at least about 10 percent.

In connection with the intrinsic viscosity of the polymer, another advantage of this invention is realized. Normally, propylene polymers of the type herein employed are extremely sensitive to thermal and stress degradation, the problem being quite acute with high molecular weight (i.e., high intrinsic viscosity) polymers since these require a large amount of energy for forming. As pointed out above, when large polymer particles are dispersed in the second phase, a large amount of diffusion between the phases is required in order to form a reasonably uniform solution from which a continuous phase can be prepared. This requires a relatively large amount of time and agitation or other type of working at the solution temperature, with resultant opportunity for degradation. The small particles of the present invention, having been uniformly dispersed, provide minimum inter-particle distances and short paths for diffusion of the second phase into the polymer particles so that little flow or diffusion between phases is necessary to form a solution and the mass need not be exposed to the elevated temperature for very long. The particles employed in the practice of this invention are so small that the requisite diffusion can be effected without the necessity for prolonged agitation, milling, or other work. Thus, substantially less degradation occurs and the viscosity of the polymer ultimately present will be higher than would be the case in a composition prepared from the same ingredients and blended to the same degree of uniformity using large particles.

Due to the limited amount of diffusion required to form uniform solutions and the resulting ability to prepare such solutions without the necessity for working the mass as by milling or the like, shaped structures of the compositions of this invention can readily be prepared by simply forming the dispersion into the desired shape, heating to effect solution of the polymer in the second phase and cooling to solidify the mass and form the desired continuous disperse phase. Since the propylene polymer particles are not dissolved at the time of the forming, they contribute very little to the viscosity of the composition. Accordingly, any technique normally used for forming the amorphous second phase can be employed, e.g., extrusion, injection molding, compression molding, knife coating, spraying, organosol or plastisol fusion, and the like, depending on the melt viscosity of the second phase.

In addition, the small particles are readily suspended in liquid media, and when dispersed, remain dispersed in the liquefied second phase. Larger particles, such as the micron and larger particles known to the prior art, settle out rapidly from suspension, which leads to difficulties in handling during the forming steps, as well as to non-uniformity of the product after fusion and cooling.

Yet another advantage of the present invention is the greater range in the thickness of the finished product resulting therefrom as compared to that prepared from prior art compositions. Using large particles of the propylene polymer to prepare, e.g., a coating film of one of these compositions, it would not be possible in most cases to form a useful coating in situ by fusion of a dispersion as contemplated herein due to the difficult diffusion between phases to form a uniform coating solution. When such a coating is formed, it is necessarily a thick coating because of the relatively great size of the initial polymer flakes. In situ coatings are readily formed from the compositions of this invention and since the particles are very small, such coatings can be made extremely thin.

In order to incorporate the particulate propylene polymer into the amorphous phase, it is necessary to fluidify the amorphous phase, if it is not already fluid, and to disperse the polymer uniformly throughout the fiuidified second phase while the polymer is still in solid, non-viscous form. This fluidification can be effected either by the use of heat or by dissolving the amorphous material in a suitable solvent. When the second phase has been fluidified, the particulate polymer is incorporated therein by any convenient means. For example, a Banbury mixer, a roll mill or similar compounding apparatus can be employed or simple agitation in the case of low viscosity materials. Care must be exercised to assure that the physical state of the propylene polymer is not affected by the temperature of the system during this incorporation. Blending is continued for a long enough time to form a homogeneous dispersion of the particulate polymer in the fluidified second phase. In the case where liquefaction is effected by means of a solvent, the blending can frequently be effected by less vigorous mixing techniques, e.g., simple propeller blade agitation.

The temperature at which the mixture of propylene polymer and the amorphous second phase material is heated to effect fusion into a continuous phase will depend on the specific polymer used, the nature of the second phase material, e.g., its theta temperature for the polymer, its solvating effect for the propylene polymer, its fluidity, etc., but must be a. temperature sufficient to dissolve the polypropylene in the second phase material. In general, it will be a temperature within the range of about 120 C. to about 250 C., and preferably will be from about 120 C. to about 200 C.

The first phase of the polyphase compositions according to this invention comprises the crystallizable propylene polymer present as a substantially continuous network of the polymer, in either the monoclinic or the smectic state, and which is essentially non-spherulitic. It is well recognized that the division of polymer structure into crystalline and amorphous phases is an over-simplification, and more likely there exists a gradation in structural organization between these extremes. Yet in practice, the degree of crystallinity parameter is a useful concept in correlation of structure with physical properties. In the specific case of polypropylene structure, three unique levels of order are readily differentiated by standard X-ray diffraction methods. The amorphous state is characterized by a single broad diffraction maximum at l7.020 diffraction angle. The crystalline state is characterized by multiple well-defined maxima. Those of the alpha or monoclinic form occur at 14.0, 16.8, 18.5 and 2l.820. Those of the beta or hexagonal form occur at 150 and 2 1329. The third state represents a condition of intermediate order called variously, the para-crystalline" or smectic state which is characterized by two quite broad rather than sharp difiraction maxima at 15 and 2120. This quasi-crystalline state, here called the smectic state, has short range order which differentiates it from the amorphous state but lacks the long range order associated with true crystals.

Polypropylene can exist in several polymorphic crystalline forms as is shown by their unique X-ray diffraction spectra discussed above. These forms are also readily observable under the polarizing microscope as spherical arrays of dendritic crystallites. Electron microscopy has recently revealed these dendrites to be regularly folded chain crystals having a fold period of a few hundred angstroms. The dendrites emanate from the nucleus, growing by non-crystallographic branching until. their growth is constrained by impingement with dendrites from neighboring spherulites. These spherulitic structures fill the free volume. But since the observed (as opposed to the theoretical) degree of crystallinity as measured by density or X-ray is seldom more than 75 percent, appreciable uncrystallized polymer chains which are rejected during crystallization are segregated within and to a lesser extent between spherulites. The spherulite is, then, a two-phase structure with extensive folded-chain crystalline regions and amorphous regions as shown by heavy metal electron staining.

In contrast to the spherulitic crystalline state, the polypropylene which, in the polyphase compositions of this invention, is in the monoclinic or smectic state exhibits only a fine fibrous structure by electron microscopy. Unless the preponderance of the propylene polymer is in this fine fibrous non-spherulitic form, the polymer phase of the resultant compositions is not continuous and the properties exhibited by the compositions will be primarily those of the second phase. Reference herein to crystallization of the propylene polymer, when the polyphase compositions are formed, is to precipitation or crystallization of the propylene polymer to the monoclinic or smectic state.

In many instances, depending on the characteristics of the second phase material, storage conditions, and the like, the propylene polymer, if it is in the smectic form in the polyphase composition, may, on aging, slowly convert to the monoclinic crystalline form. The higher the temperature to which the polyphase composition is exposed, the more rapid is this conversion. In such cases the monoclinic polymer that is formed will be non-spherulitic and will still be in the extended form. Thus, the propylene polymer in the polyphase compositions of this invention will be seen to be present in an essentially wholly smectic state, or as a mixture of the smectic and monoclinic states, or as an essentially wholly monoclinic state.

The formation of the smectic or monoclinic state of the polypropylene is believed to be an effect of the degree of molecular mobility of the polymer during the period when crystallization is taking place. To prevent formation of the spherulitic crystalline form, molecular mobility must be restricted but not completely eliminated. The precise technique for controlling mobility depends upon the viscosity of the second phase while crystallinity is developing.

When the second phase rubber is of intermediate viscosity rapid cooling, as by quenching is not required, in most cases, although it is not necessarily detrimental. In these cases, it appears that the viscosity of the second phase is great enough that it can exert the necessary restraining influence or molecular mobility of the propylene polymer phase. Apparently only sufiicient movement is allowed that the polymer can form only the desired non-spherulitic crystalline state within the time available during cooling. There is usually not time for development of a complete three-dimensional spherulitic structure prior to complete solidification of the polypropylene. In some cases, it is even desirable to anneal the composition following cooling or solidification in order to promote crystallization even to the smectic crystalline state.

When the second phase is of extremely high viscosity, the viscosity is sufficiently high to immobilize the polypropylene completely, thereby preventing any crystallinity in the same upon cooling. When this is the case, a viscosity reducer must be present during the crystallization period. This can be accomplished, e.g., by having a solvent present during the crystallization period. Since most rubbers are not readily made fluid by heat alone and must be dissolved in a solvent in order to fluidize them, it is a simple matter to assure that this solvent remains until after the propylene polymer has solidified. If the second phase is an oil extended rubber, the extending oil can function as the viscosity reducer.

The second phase is a rubber material, or combination thereof with other materials, which is essentially amorphous at 20 C. and which can be fluidified and maintained as a liquid within the temperature range between 1 and 250 C. This fluidification can be either by heating, dissolution, or both. Within the above temperature range, the fluid material must exhibit a specified degree of solubility or compatibility for the propylene polymer. The amorphous second phase rubber material is most accurately described as having a critical miscibility temperature (theta temperature) for the propylene polymer below about 160 C. and must also be fluid at the theta temperature. On the other hand, to produce solid polyphase compositions, the second phase substance must be a non-solvent for the propylene polymer at use temperatures, normally 80 C. and less. In order for the second phase material to be sufi'iciently compatible to prepare the polyphase compositions of this invention, it must have a cohesive energy density (CED) between about 45 and 100.

The second phase materials are those substances having a CED within the range specified above and which are substantially non-polar in nature. Examples of such materials are natural rubber and synthetic elastomers such as poly(isobutylene), poly(butadiene), poly(isoprene), neoprene, GR-S, butadiene-acrylonitrile copolymers, chlorinated and chlorosulfonated polyolefins, chlorinated butyl rubber, amorphous polyethers such as amorphous poly(epichlorohydrin), amorphous epichlorohydrin-alkylene oxide copolymers, propylene oxide-allyl glycidyl ether copolymers, propylene oxidebutadiene monoxide copolymers, etc. and ethylenepropylene copolymer rubbers. The latter can be either copolymers of ethylene and propylene alone or a terpolymer of these olefins with a diolefin such as, e.g., 1,5-hexadiene, or dicyclopentadiene. They are prepared by solution polymerization of the desired olefins in the presence of a vanadium compound as a catalyst. Such elastomers are completely amorphous, and have a molecular weight within the range of about 100,000 to about 500,000.

All of the above are substantially amorphous materials which can be benefitted in one or more ways by addition thereto of a continuous propylene polymer network. Benefits which can be effected include a stiffening action or increased modulus resulting from the polymer network, a reduction in surface tackiness or blocking tendency, reduction of cold flow and creep characteristics, increased strength and elongation, and modification of flow characteristics by a means other than chemical cross-linking.

All of the compositions do, however, contain the propylene polymers as a continuous phase which can be clearly seen if the amorphous material is extracted with a solvent which dissolves the amorphous phase without dissolving the propylene polymer. After the extraction, the propylene polymer remaining is in the form of a tough, coherent, elongatable sheet or film. By contrast, after extraction of the amorphous phase from compositions prepared with large particle propylene polymers, the remaining polymer is a weak structure having virtually no strength and which is easily reduced to a powder.

The unique propylene polymers employed in the preparation of the compositions of this invention are in the form of tiny particles which have an average particle size between about 0.02 and 0.5 micron in size, with at least 75 percent of the particles being about 0.1 to 0.4 micron in size with substantially no irreversible clusters of particles greater than about 5 microns.

The efficacy of the polymer for use in the invention does not depend upon any particular method of preparing the same, so long as its particle size is within the prescribed range. Although the preparation of the very tiny particles to be employed forms no part of this invention, the following description is presented to illustrate one very useful method of preparing propylene polymer particles within the useful range.

Such small particles of polypropylene are prepared by polymerizing propylene in the presence of a colloidal dispersion of a trivalent titanium-containing catalyst. It is well known that an a-olefin such as propylene can be polymerized with the aid of catalysts containing organometallic compounds in combination with transition metal compounds. Particularly effective catalysts for this purpose are combinations of alkylaluminum compounds and titanium compounds. When preparing the tiny particles of crystalline polypropylene, it is necessary first to prepare a colloidal trivalent titanium-containing catalyst and then use this catalyst in combination with an aluminum alkyl compound to polymerize the propylene, thereby obtaining a colloidal dispersion of the polymers. Any titanium trichloride can be used for the preparation of the colloidal catalyst provided that it contains, if any, only a minor amount of the beta form of the titanium trichloride. A particularly active titanium trichloride-containing catalyst is obtained by reducing titanium tetrachloride at low temperature with an aluminum alkyl such as an alkylaluminum sesquichloride and then heat treating the precipitate so obtained. A colloidal dispersion of the trivalent titanium catalyst is then prepared by suspending it in any convenient inert hydrocarbon diluent, as for example, n-heptane, kerosene, etc. To this suspension is then added a dialkyaluminum halide such as diethylaluminum chloride or diisobutylaluminum chloride, in a ratio of from about 0.1 to about 4.0 aluminum per titanium. Other catalyst components can be used in conjunction with the titanium and aluminum components such as Lewis bases, as for example, anisole. There is then added from 3 to 40 moles per mole of titanium of a straight chain a-olefin containing at least six carbon atoms. Exemplary of the a-olefins that may be used for this purpose are: n-hexene-l, n-octene-l, decene-l, undecene- 1 dodecene-l and hexadecene-l. The polymerization of this long chain a-olefin is generally carried out at moderate temperatures, as for example, from about 30 C. to about 70 C. There is obtained by this process a colloidal suspension of the trivalent titanium-containing catalyst. This colloidal suspension can be used at once or stored until desired.

The propylene polymerization process is carried out by adding to a suitable liquid organic diluent, as for example, a saturated aliphatic, cycloaliphatic, or aromatic hydrocarbon, an aluminum alkyl activator such as diethylaluminum chloride or ethylaluminum chloride alkoxide, in an amount of from about 5 to 10 millimoles per liter of diluent. Exemplary of the diluents that can be used are: hexane, heptane, octane, decane, cyclohexane, benzene, toluene, xylene, and mixtures of such hydrocarbons, as for example, high and low boiling kerosene and other such petroleum fractions, chlorinated aromatic hydrocarbons, highly hindered aliphatic ethers, sulfides, etc., such as di-t-butyl ether, aromatic ethers such as diphenyl ether and other inert liquid organic diluents and liquid propylene itself. The colloidal dispersion of trivalent titanium catalyst is then added and the propylene is introduced at a very slow rate so as to increase the pressure gradually to p.s.i.g. or higher, which pressure is maintained until the polymerization is complete. Hydrogen can be added if desired to produce a lower molecular weight polymer. The polymerization is generally carried out at a temperature of from about 30 C. to about C. The length of time the polymerization is carried out will be dependent upon the solids content desired or until the viscosity of the reaction mixture becomes too great for easy agitation. The polymerization is stopped by adding a small amount, as for example 2 volume percent based on the original volume of diluent, of an alcohol such as n-butanol. The catalyst residues are removed by any of the usual means utilized in the purification of polyolefins, such as for example, an acid, water or basic wash, treatment with an ion exchange resin or any other convenient means.

The crystallizable propylene polymers which can be employed as the continuous phase of the compositions of this invention include propylene homopolymer and copolymers of propylene with up to about 25 percent of a second a-olefin having two to 20 carbon atoms. Exemplary copolymers are those of propylene with ethylene, butene-l pentene-l 3- methylbutene-l, 4-methylpentene-l, hexene-l, octene-l, decene-l dodecene-l, tetradecene-l, hexadecene-l octadecene-l, eicosene-l styrene and substituted styrenes such as haloand alkyl-substituted styrenes, for example, p-chloroand p-methylstyrene.

Preferably, the copolymer is of the type prepared by simultaneous polymerization of the olefins so that the minor olefin is randomly distributed throughout the copolymer molecule. In this type copolymer, about 8 weight percent of a minor olefin is the upper limit. This will vary with different olefins, being less with the higher olefins than with, e.g., ethylene or butene-l.

In some cases, the copolymer can be an end-block type copolymer. This type copolymer is prepared by first polymerizing a portion of propylene alone, followed by a portion of the minor olefin and thereafter, if desired, alternating the two olefins. This type copolymer is characterized by remaining crystallizable at higher concentrations of the minor olefin than does the random type. Thus, employing the endblock technique, crystallizable copolymers with, e.g., ethylene as the minor olefin, can be prepared having up to 25 weight percent of the minor olefin. When the minor olefin is a long chain olefin, as, e.g., tetradecene-l, this upper limit will be less, usually not more than about 10 to 12 weight percent.

When it is desired to produce a copolymer of propylene with a second gaseous olefin, the same procedure as described for preparing polypropylene is followed except that the monomer gas is a mixture of propylene and the second olefin or olefins in the ratio required to yield the correct ratio in the final products. This ratio depends upon the relative polymerization ratio of the olefins and is readily calculated by those skilled in the polyolefin art.

If the second olefin is a liquid, the total amount of such olefin to be used can be dissolved in the reaction diluent prior to the addition of any propylene gas or it can be used as the diluent. Alternatively, the second olefin can be added continuously throughout the reaction time period as is done with gaseous olefins. In either case, the ratio of the monomers depends upon the desired final ratio and on the polymerization reactivity of the second olefin relative to propylene.

The polypropylene, as it is prepared, is in the form of a colloidal dispersion of the particles in the hydrocarbon reaction diluent. Such dispersions usually are on the order of about 20 to 30 percent solids, i.e., polymer content, although this can be varied either by polymerization conditions or by dilution or concentration after completion of polymerization.

The polymer can be used in the process of the invention in the colloidally dispersed form recovered from the polymerization, or it can be separated from the dispersion and used in the form of dry solid particles. In the former case, provision must be made for removal of the solvent at a later time, at some point in the process after the polymer has been dispersed in the amorphous material. If dry polymer is to be used, the polymer is readily separated from the diluent by such methods as spray drying, vacuum stripping, drum drying, or by centrifuging, followed by evaporation of residual diluent. This must, of course, be efiected at a low enough temperature that no significant amount of softening of the particles can take place. Preferably, diluent removal is carried out at less than about 60C.

Any of the usual additives can also be incorporated in these polyphase compositions, as for example, pigments and pigment dispersants, dyestuffs, heat and light stabilizers and antioxidants, plasticizers, fillers, and the like.

The invention is illustrated by the following illustrative examples.

EXAMPLE 1 To a nitrogen filled reaction vessel, equipped with a magnetic stirring bar, was added 496 millimoles of isobutyl-aluminum sesquichloride as a 1.12 M solution in a refined kerosene (boiling range of 165-200 C.). With the temperature adjusted to 2- C., there was added to the stirred solution, in one addition, 240 millimoles of titanium tetrachloride. The mixture was stirred for 4 hours at 2-3 C., then with stirring, was allowed to warm to room temperature during 16 hours, after which it was heated to 150 C. during 2 hours, held at that temperature for 1 hour and then allowed to cool. The reaction slurry was transferred under nitrogen to a centrifuge, the supernatant was discarded and the titanium trichloride-containing precipitate was washed under nitrogen three times with n-heptane by agitation and centrifugation each time. It was then brought back to its original volume with n-heptane. Analysis showed it to be 0.575 M in titanium.

A nitrogen filled reaction vessel was charged with 1.4 l. of nheptane, 16.8 millimoles of diethylaluminum chloride and an amount of the above prepared titanium trichloride containing catalyst equal to 35 millimoles of titanium. With the temperature adjusted to 50-52 C., there was then added 525 millimoles of octene-l and the mixture was held at 50-5 2 C. for 1 hour.

To a reaction vessel, held at about 50 C., and containing 15.41. of n-heptane under nitrogen was added l60 millimoles of the reaction product of diethylaluminum chloride with a molar equivalent of 2-ethylhexanol. The above prepared colloidal dispersion of titanium trichloride catalyst was added and propylene was then slowly admitted to a pressure of about 45-50 p.s.i.g., which pressure was maintained for 5 hours. The reaction was stopped by adding 340 ml. of n-butanol and the reaction mixture was stirred for 16 hours at 50 C. The reaction mixture was stirred under nitrogen with 4 percent aqueous hydrogen chloride for 3 hours at room temperature and then washed three times with water. The colloidal polypropylene dispersion so obtained had a solids content of 21 percent, of which 9.9 percent was soluble in decahydronaphthalene and had an intrinsic viscosity of l 1.9. The average primary particle size of the polypropylene was 0.2-0.3 micron; many of the particles were present as reversible clusters of l to 5 microns in size.

EXAMPLE 2 A nitrogen filled reaction vessel, equipped with an agitator and cooled to 0 C. by ice water, was charged with one mole of titanium tetrachloride added as a 25 percent solution in a purified petroleum fraction (having a boiling range of l65-200 C.). Over a period of 4 hours, there was then added 1.3 moles of ethylaluminum sequichloride as a 25 percent solution in the purified petroleum fraction. The reaction mixture was agitated an additional 2 hours at 0 C. and then was allowed to warm to room temperature, after which it was heated to -85 C. for 3 hours to complete the reduction of tetravalent titanium to trivalent titanium. The titanium trichloride-containing precipitate was separated and washed with portions of kerosene, after which it was held at C. for 24 hours to complete the activation of the catalyst.

A nitrogen filled reaction vessel was charged with 17.2 1. of n-heptane, 172 millimoles of diethylaluminum chloride, and an amount of the above prepared titanium trichloride-containing catalyst equal to 60 millimoles of titanium. With the temperature adjusted to 50 C., there was then added 0.9 mole of octene-l. After 1.25 hours at 50 C., propylene was slowly added to a pressure of about 45-50 p.s.i.g., which pressure was maintained throughout the reaction. About 1 hour after the start of the propylene addition, hydrogen was admitted and maintained at about 5 mole percent in the gas phase. The reaction was stopped after 4.25 hours by adding 350 ml. of nbutanol. The polypropylene dispersion so obtained was purified as described in Example 1. It had a solids content of l 8.7 percent, of which 7.1 percent was decahydronaphthalene soluble and an intrinsic viscosity of 3.1. The average primary particle size was 0.2-0.3 micron and many particles were present as reversible clusters of 0.5 to 5 microns in size.

EXAMPLE 3 A 16.7 percent solution of polyisobutylene having a molecular weight of about 140,000 was prepared in a petroleum hydrocarbon fraction boiling at 188 C. to 210 C. To 50 parts of this solution was added 15.4 parts of an 18 percent dispersion of polypropylene in the same hydrocarbon fraction. The polymer had an intrinsic viscosity of 9 and its average particle size was about 0.3 micron. The polymer was stabilized with 0.25 percent distearyl thiodipropionate (based on polypropylene) and 0.5 percent of the reaction product of 1 mole of 4,4-n-butylidene-bis(2-t-butyl-5-methylphenol) and 2.5 moles of diphenyl isooctyl phosphite.

Simultaneously, a dispersion was prepared in the same proportions of polypropylene, polyisobutylene, and diluent, except that the polypropylene was in the form of particles of about 35 microns average size.

Films of the above dispersions and a control of the polyisobutylene solution were cast on a 3 l-gauge steel panel, covered with another panel to retard solvent evaporation, baked 4 minutes at 168 C. then quenched in cold tap water. The films were extracted with isopropanol to remove solvent and air dried. The film prepared from the small particle dispersion was white and non-tacky and had an elastic, rubbery response when pulled and stretched. The other films were tacky, and weak, and broke readily when pulled.

EXAMPLE 4 Compositions were prepared containing an oil-extended ethylene--propylene copolymer rubber comprising 58 percent ethylene and 42 percent propylene and polypropylene. The polypropylene had an average particle size of 0.3 micron and intrinsic viscosity of X2 and was stabilized against thermal degradation. The composition contained 90 parts by weight copolymer, 30 parts extending oil, and 30 parts of dry polypropylene particles. The polypropylene was incorporated by milling on a 2-roll mill at 160 C. for about 5 minutes.

This composition was compression molded for 5 minutes at 204C. into a A; inch disc, then cooled in the mold over a period of 8 minutes. A control specimen was prepared concurrently with the above composition but containing no polypropylene.

The disc containing the small particle polypropylene was hard, stiff and virtually tack-free. The composition containing only rubber and extending oil was a soft, tacky rubber.

EXAMPLE 5 A dispersion was prepared as follows:

Ethylene-propylene rubber 8 parts Polypropylene (0.3 micron) 2.81 parts High-boiling aliphatic hydrocarbon (196-255" C.) 8.9 parts Low-boiling aromatic hydrocarbon (l882l0 C.) 92 parts (1) 587: ethylene, 42% propylene (2) I.V,oi' l 1.4.

Cooling Rate Appearance Rubber A Transparent, slightly tacky,

highly elastic Rubber B Transparent, slightly tacky,

highly elastic Rubber C Transparent, slightly tacky,

highly elastic Rubber polypropylene A Translucent, non-tacky, tough and elastic Rubber polypropylene B Translucent, non-tacky, tough and elastic Rubber polypropylene C Translucent, non-tacky, tough and elastic The above demonstrates both the modifying effect of the polypropylene in this type composition and the relative insensitivity to cooling rate. When the same compositions were fused under conditions such that solvent escaped during the fusion, the same insensitivity to cooling rate was observed but no difference between the compositions could be noted due to the presence of the polypropylene. This indicates the desirability of having a solvent present during cooling to provide the necessary degree of polypropylene mobility for forming a continuous phase in the presence of a highly viscous second phase.

EXAMPLE 6 A blend of natural rubber and polypropylene was prepared following the procedure described in Example 3 but substituting natural rubber for the polyisobutylene used in that example. The film prepared, as described in that example, from the polypropylenenatural rubber dispersion was non-tacky and elastic,

What I claim and desire to protect by Letters Patent is:

l. A process for preparing solid polyphase compositions containing:

A. as a continuous phase, from about 5 to about 60 percent by weight of a crystallizable propylene polymer selected from the class consisting of propylene homopolymer and copolymers of propylene with a second a-olefin having two to 20 carbon atoms being present as a substantially continuous network in the crystalline but essentially nonspherulitic state, and having an intrinsic viscosity of at least about 2, and

B. as a second phase, from about to about 40 percent by weight of a substantially amorphous organic material selected from the group consisting of natural and synthetic hydrocarbon rubber which process comprises fluidifying said amorphous material and uniformly dispersing therein said propylene polymer in the form of particles having an average size of 0.02 to 0.5 micron, heating the total composition to a temperature at which the propylene polymer dissolves in the amorphous material and cooling.

2. The process of claim 1 where the propylene polymer is polypropylene.

3. The process of claim 2 where the amorphous phase is ethylenepropylene copolymer rubber.

4. The process of claim 1 where the composition is shaped prior to fusion to form the continuous propylene polymer phase.

5. The process of claim 4 where the shape is a film adhered to a substrate.

6. The process of claim 1 where the amorphous second phase is rendered fluid by dissolving the same in a solvent at a temperature below that at which the propylene polymer melts or dissolves in the resulting solution.

7. The process of claim 1 where the cooling of the propylene polymer-amorphous phase solution is effected in the presence of a solvent for the amorphous phase. 

2. The process of claim 1 where the propylene polymer is polypropylene.
 3. The process of claim 2 where the amorphous phase is ethylene-propylene copolymer rubber.
 4. The process of claim 1 where the composition is shaped prior to fusion to form the continuous propylene polymer phase.
 5. The process of claim 4 where the shape is a film adhered to a substrate.
 6. The process of claim 1 where the amorphous second phase is rendered fluid by dissolving the same in a solvent at a temperature below that at which the propylene polymer melts or dissolves in the resulting solution.
 7. The process of claim 1 where the cooling of the propylene polymer-amorphous phase solution is effected in the presence of a solvent for the amorphous phase. 